Method for operating a water electrolysis device

ABSTRACT

A method for operating a water electrolysis device produces hydrogen and oxygen from water. In the electrolysis device, water which comes from a PEM electrolyzer ( 1 ) is fed to a first heat exchanger ( 10 ) for cooling, subsequently to an ion exchanger ( 11 ), then to a second heat exchanger ( 12 ) for heating and again to the PEM electrolyzer ( 1 ), in a water circuit ( 4 ). The heat exchangers ( 10, 12 ) form part of a common heat transfer medium circuit ( 20 ) at a secondary side. The heat transfer medium circuit includes a cooling device ( 24 ), through which the heat transfer medium flow is selectively led in a complete or partial manner or not at all, for the control and/or regulation of the temperature of the water which is fed to the ion exchanger ( 11 ) and/or to the PEM electrolyzer ( 1 ).

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a United States National Phase Application of International Application PCT/EP2017/059628, filed Apr. 24, 2017, the entire contents of which are incorporated herein by reference.

TECHNICAL FIELD

The invention relates to a method for operating a water electrolysis device for producing hydrogen and oxygen, in which in a water circuit, water which comes from a PEM electrolyser is fed to a first heat exchanger for cooling, subsequently to an ion exchanger, then to a second heat exchanger for heating and again to the PEM electrolyzer, as well as to a water electrolysis device for carrying out this method, for producing hydrogen and oxygen from water, in which a PEM electrolyzer, a first heat exchanger, an ion exchanger and a further heat exchanger whose exit is conductively connected to the PEM electrolyzer are successively arranged in a conduit circuit.

TECHNICAL BACKGROUND

A water electrolysis device of EP 1 243 671 A1, with which a PEM electrolyzer is incorporated into a water circuit is counted as belonging to the state of the art. The water which is fed to the PEM electrolyzer is broken up into hydrogen and oxygen, wherein the excess water together with the oxygen is fed to a gas separation container, whose fluid-leading exit conduit is fed to a cooling device and subsequently via a filter back to the PEM electrolyzer. The water which is broken up into hydrogen and oxygen on electrolysis is replaced by demineralised water and is fed to the gas separation container.

During the operation of this electrolysis device, metal ions are released in the PEM electrolyzer, which these negatively influence the electrolysis process on renewed feeding of the water and damage the PEM electrolyzer. This can be prevented by way of the upstream arrangement of an ion exchanger, but this demands a temperature reduction of the fed water, in order not to exceed a highest permissible temperature of approx. 60° C. The reduction of the water temperature however worsens the performance and efficiency of the PEM electrolyzer, said PEM electrolyzer preferably being operated with water of a temperature between 70° and 80° C. or higher. Concerning the device which is known from EP 1 243 671 A1, such a temperature reduction is made possible by way of forgoing an ion exchanger which is arranged upstream of the PEM electrolyzer, wherein it is to be ensured that the metal ion content of the water fed to the PEM electrolyzer does not exceed a tolerable value by way of the continuous feed of demineralized water.

A water electrolysis device of EP 2 792 769 A1, in which an ion exchanger is arranged upstream of the PEM electrolyzer in the conduit circuit, is counted as belonging to the state of the art. In order here on the one hand not to exceed the temperature which is permissible for the ion exchanger and on the other hand to feed water which is at a higher temperature than that which exits from the ion exchanger to the PEM electrolyzer, a heat exchanger is provided there and this at the primary side leads the water which is fed to the ion exchanger and on the secondary side the water which is led away from the ion exchanger, in a counter-flow, in order to improve this temperature problem. Herein however, a cooling device is additionally necessary between the heat exchanger and the ion exchanger, in order to ensure the entry temperature which is necessary for the ion exchanger. One problem of this arrangement is the fact that the same water quantities must always be led through the heat exchanger which is arranged upstream, at the primary side and at the secondary side, since they lie in the same conduit circuit. The regulator of the cooling device in practice has been found to be insufficient, in order to meet these contradictory temperature demands.

SUMMARY

Starting from this state of the art, it is the object of the invention to improve a method for operating a water electrolysis device to the extent that the aforementioned problems are reduced, in particular that the electrolysis can be improved in its performance and efficiency. Furthermore, a water electrolysis device, with which such an improved method can be carried out, is to be provided.

The method according to the invention for operating a water electrolysis device for producing hydrogen and oxygen, with which in a water circuit water coming from a PEM electrolyzer is fed to a first heat exchanger for cooling, subsequently to an ion exchanger and then to a second heat exchanger for heating and again to the PEM electrolyzer, is characterised in that the heat exchangers at the secondary side form part of a common heat transfer medium circuit, wherein the heat transfer medium circuit comprises a cooling device, through which the heat transfer medium flow is led selectively in a complete or partial manner or not at all, for the control and/or regulation of the temperature of water fed to the ion exchanger and/or of the temperature of the water fed to the PEM electrolyzer.

A basic concept of the method according to the invention is to do firstly without a cooling device in the water circuit of the electrolyzer and instead of this to control, preferably regulate (closed-loop control) either the temperature of the water fed to the ion exchanger or the temperature of the water fed to the PEM electrolyzer or both temperatures, by feeding the heat transfer medium flow which is led through the heat exchangers at the secondary side completely, partly or not fed at all, to a cooling device depending on the requirements. Herein, the cooling device is preferably connected in parallel to the second heat exchanger via a mixing valve, so that the heat transfer medium flow which exits from the cooling device is firstly fed to the first heat exchanger and then completely or partly to the second heat exchanger or again to the cooling device. Given the application of a suitable control and regulation device, with this arrangement either the temperature of the water fed to the PEM electrolyzer can be regulated in the necessary manner, or the temperature of the water fed to the heat exchanger. If, as is likewise envisaged according to the invention, both these temperatures are to be regulated, then it will be necessary to provide a further regulator (actuator) and this for example can be the power of the cooling device, thus the cooling power and/or the throughput through the heat transfer medium circuit, said throughput being able to be varied for example by way of a suitable control of a speed-controllable circulation pump.

Alternatively, according to the invention, the cooling device of the heat transfer medium circuit can be arranged upstream of the first heat exchanger in the through-flow direction which is to say in series with this. The throughput which is fed to the second heat exchanger or which is fed to the cooling device whilst bypassing of the second heat exchanger is then controlled via a mixing valve. The cooling device is to be controllable in its power given such an arrangement.

A basic concept of the method according to the invention is therefore not to cool the water circuit in a direct manner, but to incorporate a cooling device in the secondary circuit, wherein advantageously both heat exchangers are assigned to the same heat transfer medium circuit and the temperature control or regulation is effected merely by way of leading the heat transfer medium through a cooling device in a complete or partial manner or not at all.

A PEM electrolyzer in the context of the present invention is typically to be understood as a stack of PEM electrolyzer cells as it is counted as belonging to the state of the art. Herein, it can possibly also be the case of a multitude of PEM electrolysis cells which are connected in parallel in another form or shape. The first and second heat exchangers also do not necessarily need to consist of a single heat exchanger, and herein it can also be the case of one or more individual heat exchangers which are connected in parallel and/or series. This analogously applies to the cooling device and to the ion exchanger, wherein the cooling device typically comprises a heat exchanger, whose primary side lies in the heat transfer medium circuit and through whose secondary side a cooling medium, for example air or cooling fluid from a cooling assembly can flow.

In the present application, on the one hand the terms water circuit or conduit circuit and on the other hand the term heat transfer medium circuit are used throughout. Water circuit or conduit circuit denotes the primary circuit, in which the PEM electrolyzer and the ion exchanger lie, and heat transfer medium circuit denotes the secondary circuit which at the secondary side leads through the heat exchangers which are arranged upstream or downstream of the ion exchanger but which can be operated in the same manner with water as a heat transfer medium. Here, it is typically not demineralised or distilled water which is used but common tap water, possible amid the admixing of glycerine or also other additives.

In order to increase the service life of the PEM electrolyzer, said PEM electrolyzer typically being designed as a stack, and hence to also increase the performance over the longer term, according to a further development of the invention one envisages periodically reversing the throughflow direction through the PEM electrolyzer, wherein according to the invention it is not compellingly the case of always achieving equally long throughflow intervals in each direction, but of a more or less uniform distribution over the operational duration. Periodically in the context of the invention is therefore not to be understood in the strict mathematical sense, but in the context of alternating. Herein, it is preferably such that the reversal is not effected during the operation, but after the shutting down of the electrolysis device or before the starting-up, when this has been at a standstill in any case. However, if the electrolysis device runs in a continuous manner, then such a reversal can also possibly be effected during the operation. This measure of changing the flow direction through the PEM electrolyzer can furthermore also be applied independently of the aforementioned method, thus also on operation of electrolysis devices according to the state of the art, as have been mentioned beforehand by way of example.

According to an advantageous further development of the method according to the invention, one envisages the leading the water circuit past the PEM electrolyzer via a bypass conduit on starting up the water electrolysis device. This measure can also be effected independently of the methods which are specified in claims 1 and 2. This measure likewise contributes to the long service life of the PEM electrolyzer, since ion exchangers, when they are not subjected to throughflow but the medium therein is at a standstill, as with a shut-down electrolysis device, typically have the characteristic of releasing metal ions to the water, said metal ions then getting into the PEM electrolyzer with the next start-up of the device and damaging this. This can be effectively prevented by leading through the bypass on starting up. The metal ions which are located in the water circuit are then removed given a renewed flow through the ion exchanger.

In order to bring the power of the PEM electrolyzer as quickly as possible to a high level on starting up the electrolysis device, according to a further development of the invention one envisages the water which is fed to the PEM electrolyzer being preheated by way of a heating device. This is typically effected by way of an electrical heater which heats the water which is cold on starting up the device, in the manner of a continuous heater. This measure compliments the regulation according to the invention in an ideal manner, said regulation initially not yet functioning in the desired manner given too low a temperature in the water circuit. The heating device does not necessarily have to be arranged in the primary circuit, but can also be arranged in the heat transfer medium circuit, for example upstream of the further heat exchanger in the throughflow direction, said further heat exchanger in any case serving for the heating of the water fed to the PEM electrolyzer.

The water electrolysis device according to the invention for producing hydrogen and oxygen from water comprises a conduit circuit for the distilled, at least demineralised water, in which a PEM electrolyzer, a first heat exchanger, an ion exchanger and a further heat exchanger are successively arranged, wherein the exit of the further heat exchanger is conductively connected to the PEM electrolyzer. The water-leading exit of the PEM electrolyzer is typically the oxygen-leading exit, from which water and oxygen simultaneously exit, these being subsequently separated, wherein the water is fed in the conduit circuit. According to the invention, the first as well as the further heat exchanger are incorporated into a common heat transfer medium circuit at the secondary side, wherein a cooling device which can be variably incorporated into the heat transfer medium circuit via a controllable fitting is assigned to this heat transfer medium circuit. Herein, the cooling device is also preferably controllable itself with regard to its cooling power, and alternatively or additionally a control via the throughput speed in the heat transfer medium circuit can be provided.

A basic concept of the water electrolysis device according to the invention is to assign the heat exchangers upstream and downstream of the ion exchanger to a common, secondary-side heat transfer medium circuit whilst forgoing a cooling device in the conduit circuit and to incorporate a cooling device into this heat transfer medium circuit, said cooling device being able to be incorporated into the heat transfer medium circuit in a complete or partial manner or not at all, via a controllable fitting, preferably in an infinite manner.

According to a further development of the invention, the water electrolysis device comprises a control and regulation device which controls the fitting or the cooling device or both for the purpose of temperature regulation of the water which is fed to the ion exchanger or to the PEM electrolyzer or to both. The regulation device is preferably designed for the temperature regulation of the water which is fed to the PEM electrolyzer, since this temperature is decisive for the performance of the whole device.

Since, in the process, typically more heat is to be dissipated in the conduit circuit than is necessary for heating the water which is to be fed to the PEM electrolyzer, according to the invention a stepwise regulation can also be effected, this being of a nature such that the water temperature which is fed to the PEM electrolyzer is primarily regulated and the water temperature which is fed to the ion exchanger is merely regulated with regard to a limit temperature, wherein this limit temperature for example is maximally 60° C.

According to an advantageous further development of the invention, the fitting is a mixing valve (also called mixer) as for example is counted as belonging to the state of the art from heating technology. Such a mixing valve can be controlled by way of a servomotor and can be provided in a cost-effective manner. Since it is the case of the (secondary-side) heat transfer medium circuit, here a simple, tried and tested and inexpensive fitting from heating technology can be used.

According to an advantageous further development of the invention, a speed-controllable circulation pump whose speed is controlled by the control and regulation device is arranged in the heat transfer medium circuit. Such circulation pumps which are typically controlled by frequency converters are likewise inexpensively available from heating technology and can operate in wide power ranges. The use of such a circulation pump not only makes sense if the delivery flow is to be used as a further control variable for a regulation, but also if this requirement is not given in order to be able to operate the heat transfer medium circuit in an energetically favorable manner.

The cooling device is advantageously connected parallel to the further heat exchanger, thus to the heat exchanger between the ion exchanger and the PEM electrolyzer, so that the heat transfer medium flow which exits from the cooling device is firstly fed to the first heat exchanger which is provided for cooling down the water which enters the ion exchanger. The fitting, in particular the mixing valve can then either be incorporated into the branching conduit which comes from the first heat exchanger and leads to the further heat exchanger or to the cooling device, or however preferably in the run-out region of these conduits, which is to say where the conduit from the further heat exchanger, the conduit coming from the cooling device and the conduit leading to the first heat exchanger meet one another. It is to be understood that the terms all relate to the designated throughflow direction. Alternatively, the cooling device can be incorporated in the conduit of the heat transfer medium circuit which leads to the first heat exchanger, and it is then preferably the case of a cooling device which can be controlled in its power. With the mixing valve one then controls which shares of the heat transfer medium flow are led through the further heat exchanger and which are led past this (bypass this).

In order to arrive as quickly as possible at a high power on starting up the electrolysis device, which is to say the electrical power uptake of the PEM electrolyzer and therefore a high as possible produced quantity of gas, according to the invention a heating device can advantageously be provided in the conduit circuit between the ion exchanger and the PEM electrolyzer. Usefully, this heating device is arranged downstream of the further heat exchanger and upstream of the PEM electrolyzer. Alternatively, such a heating device can be provided in the heat transfer medium circuit, and specifically arranged upstream of the further heat exchanger in the throughflow direction at the secondary side. The heating device does not necessarily need to be an electrical heater, but a heat exchanger can also be provided here, the other side of which for example leads the dissipated heat from a combustion engine.

According to an advantageous further development of the invention, a bypass conduit which can be shut off by way of a valve is provided in the conduit circuit parallel to the PEM electrolyzer. This bypass conduit can also be formed by a valve itself, as is yet explained further below. Such a bypass conduit is advantageous for starting up the electrolysis device, in order to lead the water circuit past the PEM electrolyzer, in order for example not to lead the water which is stagnant in the ion exchanger and which could be enriched with metal ions through the electrolyzer, but only to incorporate this water into the conduit circuit when it is ensured that the water which is fed to the PEM electrolyzer is free of metal ions to a sufficient degree, which is to say that the ion exchanger operates in an effective manner.

As initially described, in order to permit a direction reversal of the flow through the PEM electrolyzer within the conduit circuit, according to a further development of the invention a valve arrangement, with which this can be realized, is provided.

Advantageously, this can be effected by way of the provision of two 3/2 way valves, wherein one of the valves is connected to the one water connection of the PEM electrolyzer as well as to the feeding and discharging conduit of the conduit circuit and the other valve is connected to the other conduit connection of the PEM electrolyzer as well as likewise to the feeding and discharging conduit of the conduit circuit. Such 3/2-way valves are inexpensively obtainable on the market, even with the special material demands which are necessary here for the conduit circuit. The valve parts which are in contact with the water circuit are coated for example with Teflon or are titanium-coated or consist thereof.

Instead of two 3/2-way valves, a connection of the PEM electrolyzer to the conduit circuit can also be advantageously effected by way of a 4/2-way valve, wherein the two switching positions correspond to the two throughflow directions. If, instead of the 4/2-way valve, which is advantageous, a 4/3-way valve which in the third switching position connects the feeding and discharging conduit of the conduit circuit to one another is used, then by way of a single valve, the direction reversal of the flow through the PEM electrolyzer as well as the bypass function for starting up the electrolysis device can be realised with only one valve, which is advantageous.

The electrolysis device according to the invention, according to a further development advantageously comprises a start-up control which during the start-up phase leads the conduit circuit through a bypass whilst bypassing the PEM electrolyzer. This start-up control can be part of the control and regulation device, but it can also be realised independently of this and in the simplest form activates the shut-off valve to open during the start-up phase. On using a 4/3-way valve as described beforehand, this start-up control can be designed to activate the third switching position of the valve which forms the bypass.

The electrolysis device advantageously comprises a reversal control which in temporal intervals re-routes the valves which are assigned to the PEM electrolyzer, in order to achieve a reversal of the throughflow direction. This reversal control can likewise be designed as part of the control and regulation device or be designed in a separate manner.

The invention is hereinafter explained in more detail by way of one embodiment example. The various features of novelty which characterize the invention are pointed out with particularity in the claims annexed to and forming a part of this disclosure. For a better understanding of the invention, its operating advantages and specific objects attained by its uses, reference is made to the accompanying drawing and descriptive matter in which a preferred embodiment of the invention is illustrated.

BRIEF DESCRIPTION OF THE DRAWINGS

In the drawings:

The single FIGURE in a greatly simplified representation shows a circuit diagram of an electrolysis device, in which the components which are not essential to the present invention are not represented.

DESCRIPTION OF PREFERRED EMBODIMENTS

Referring to the drawings, the represented water electrolysis device comprises a PEM electrolyzer 1 which is designed in the usual form as a stack and comprises a first conduit connection 2 as well as a second conduit connection 3, with which the stack 1 is incorporated into a conduit circuit 4 which comprises a conduit 5 which leads away from the PEM electrolyzer 1 and in which the water which exits from the PEM electrolyzer 1 is led fed together with the oxygen which is produced therein to a container 6 which on the one hand serves for separating the oxygen and on the other hand serves for feeding the electrolyzer 1 with water. This container 6 is therefore a supply container. The water which is removed from the conduit circuit 4 via the electrolyzer 1 by electrolysis is fed to the container 6 via a conduit 7. Hereby, it is the case of demineralised or distilled water. The water-leading exit 8 of the container 6 is conductively connected via a circulation pump 9 to a first heat exchanger 10, whose exit is conductively connected to an entry of an ion exchanger 11, whose exit is connected to a further, here second heat exchanger 12, whose exit is connected via a 3/2-way valve 13 either to a bypass conduit 14 or to a conduit 15 which leads to the PEM electrolyzer and in which an electrical heater 16 is integrated.

The discharging conduit 5 and the feeding conduit 15 are each connected to the PEM electrolyzer 1 via a 3/2-way valve, and specifically via a first 3/2 way valve 17 which connects these conduits to the first connection 2 of the electrolyzer 1, as well as via a second 3/2-way valve 18 which connects these conduits to the second connection 3 of the PEM electrolyzer.

In normal operation, the water is led in the conduit circuit 4 by way of it exiting from the container 6 and firstly being led to the circulation pump 9 and from there through the primary side of the first heat exchanger 10. The water is cooled down to a temperature (for example below 60° C.) in this heat exchanger 10, in order to ensure that a high as permissible operating temperature of the subsequent ion exchanger 11 is not exceeded. After exit from the ion exchanger 11, the water is fed at the primary side to the second heat exchanger 12, in which this is heated to a temperature for example of 70° C. to 80° C., in order to then be fed to the PEM electrolyzer 1, either via the first connection 2 or on reversal of the throughflow direction via the second connection 3. Herein, the temperature to which the second heat exchanger 12 heats the water is selected such that the subsequent electrolysis process in the electrolyzer 1 takes its course at a high efficiency and at a high power. The water which exits from the electrolyzer 1 together with the oxygen is fed via the second connection 3 or, given a flow reversal, via the second connection 2, into the discharging conduit 5, to the container 6 where a gas separation is effected and the circuit 4 closes at the water side.

The heat exchangers 10 and 12 at the secondary side are assigned to a common heat transfer medium circuit 20 which by way of a speed-controllable circulation pump 21 feeds the heat transfer medium, typically water with an additive, which exits the first heat exchanger 10 at the secondary side, via a conduit 22 to the secondary-side entry of the second heat exchanger 12, as well as via a conduit 23 to a cooling device 24 which is arranged parallel to the second heat exchanger 12 and is incorporated into the heat transfer medium circuit via a mixing valve 25 being. The mixing valve unifies a conduit 26 which comes from the second heat exchanger 12 at the secondary side, with a conduit 27 which comes from the cooling device 24, into a conduit 28 which leads to the first heat exchanger 10. In an end position of the mixing valve 25, the cooling device 24 is not incorporated into the heat transfer medium circuit 20, and the secondary sides of the heat exchangers 10 and 12 are then conductively connected to one another via the conduits 26 and 28, and the circulation is effected via the pump 21 and the conduit 22 which connects thereto. The conduit 26 which comes from the second heat exchanger 12 is shut off with respect to the conduit 28 which leads to the first heat exchanger 10 and the conduit 27 which comes from the cooling device 24 is connected to the conduit 28, by way of changing the position of the mixing valve from this first end position into a second end position. This end position is somewhat of a theoretical nature, since the conduit 26 in practice is not completely closed. It is determined how much heat is dissipated out of the heat transfer medium circuit 20 depending on the extent of the release of the heat transfer medium flow which exits the cooling device 24 via the conduit 27, which is to say is led to the first heat exchanger 10 via the conduit 28.

A control and regulation device which is not shown in the FIGURE is provided, and this ensures that the position of the mixing valve 25 is activated such that the water which is fed to the PEM electrolyzer 1 has a predefined temperature for example of 80° C. This temperature is decisive for the performance of the PEM electrolyzer 1 and thus also for the complete electrolysis device. Basically, the water temperature which is fed to the ion exchanger 10 can also be regulated by way of activating the mixing valve 25. Since however it is not a question of maintaining a precise temperature here, but of merely ensuring that the entry temperature lies below for example 60° C., here a secondary regulation is superimposed, said secondary regulation either being effected via speed activation of the circulation pump 21 or by way of the control of the power of the cooling device 24.

This control and regulation device further ensures that on starting up the electrolysis device, thus when the water which is located in the circuit 4 does not yet have the desired operating temperature, this water is preheated via the electric heater 16. However, before such a preheating is effected, the 3/2-way valve is re-routed via a start-up control in such a manner that the PEM electrolyzer 1 is bridged by the bypass conduit 14, which is to say that the water which exits from the ion exchanger 11 and is fed through the second heat exchanger 12 is firstly not fed to the PEM electrolyzer 1, but to the leading-back conduit 5 and thus to the container 6. This activation is effected until it is ensured that the complete water which is located in the ion exchanger and which was located there gets into the leading-back conduit 5. It is only then that the valve 13 is re-routed, so that the water which is led in the water circuit 4 is fed to the heater 16 and therefore preheated, gets into the PEM electrolyzer 1.

Furthermore, the control and regulation device ensures that the 3/2-way valves 17 and 18 which determine the throughflow direction through the PEM electrolyzer 1 are re-routed in temporal intervals. In a first position, the 3/2-way valve 17 connects the feeding conduit 15 to the first conduit connection 2 of the PEM electrolyzer 1, wherein the conduit connection to the discharging conduit 5 is blocked, and in an analogous manner the second 3/2-way valve connects to second conduit connection 3 of the PEM electrolyzer 1 to the discharging conduit 5, wherein the conduit connection to the feeding conduit 15 is blocked. After re-routing both valves 17, 18 which is to occur simultaneously, the 3/2-way valve 17 connects the first conduit connection 2 of the PEM electrolyzer 1 to the discharging conduit 5 and blocks the feeding conduit 15, whereas the second 3/2 way valve connects the second conduit connection 3 of the PEM electrolyzer 1 to the feeding conduit 15 and blocks the conduit connection to the discharging conduit 5. Herewith, the PEM electrolyzer 1 is subjected to throughflow in the opposite direction.

Instead of arranging the cooling device 24 in the conduit 23, 27, thus parallel to the second heat exchanger 12, this could be arranged in the conduit 28, wherein it should then preferably be the case of a cooling device which is controllable in its cooling power. The conduit 23, 27 which is arranged in parallel to the second heat exchanger 12 would thus be retained, and then the heat transfer medium flow which is fed to the second heat exchanger 12 and which is led past (bypasses) the conduit 23, 27 in parallel would then be controlled via the mixing valve 25.

In the embodiment example which is described above, the electrical heater is arranged in the conduit 15 which leads to the PEM electrolyzer 1. Alternatively, such an electrical heater can also be arranged in the heat transfer medium circuit, typically upstream of the second heat exchanger 12 in the through-flow direction, thus in the conduit 22. Such an arrangement has the advantage that the heating does not especially need to be adapted to the demands placed on the primarily circuit, but that inexpensive components known from heating technology or other technologies can also be applied inasmuch as this is concerned.

While specific embodiments of the invention have been shown and described in detail to illustrate the application of the principles of the invention, it will be understood that the invention may be embodied otherwise without departing from such principles. 

The invention claimed is:
 1. A method for operating a water electrolysis device for producing hydrogen and oxygen, the method comprising the steps of: providing the water electrolysis device, which water electrolysis device comprises a conduit circuit, a PEM electrolyser, a first heat exchanger, an ion exchanger and a second heat exchanger whose exit is conductively connected to the PEM electrolyser, wherein the first heat exchanger, the ion exchanger and the second heat exchanger are successively arranged in the conduit circuit; in the conduit circuit, feeding water which comes from the PEM electrolyser to the first heat exchanger for cooling, subsequently feeding the water to the ion exchanger, then feeding the water to the second heat exchanger for heating and thereafter feeding the water to the PEM electrolyser; providing the heat exchangers to form part of a common heat transfer medium circuit at a secondary side; providing the heat transfer medium circuit such that the heat transfer medium circuit comprises a cooling device, through which the heat transfer medium flow is selectively completely, partially or not led, for a control and/or regulation of a temperature of the water which is fed to the ion exchanger and/or to the PEM electrolyser.
 2. A method for operating a water electrolysis device for producing hydrogen and oxygen, according to claim 1, wherein a flow direction through the PEM electrolyser is periodically reversed, after shutting down the electrolysis device.
 3. A method according to claim 1, wherein on starting up the water electrolysis device, water in the conduit circuit is led past the PEM electrolyser via a bypass conduit.
 4. A method according to claim 1, wherein on starting up the water electrolysis device, the water which is fed to the PEM electrolyser is preheated by way of a heating device.
 5. A water electrolysis device for producing hydrogen and oxygen from water, the device comprising: a conduit circuit; a PEM electrolyser; a first heat exchanger; an ion exchanger; a further heat exchanger whose exit is conductively connected to the PEM electrolyser, wherein the first heat exchanger, the ion exchanger and the further heat exchanger are successively arranged in the conduit circuit; a common heat transfer medium circuit connected to the conduit circuit; a cooling device; and a controllable fitting assigned to the heat transfer medium circuit, wherein the heat exchangers are integrated into the common heat transfer medium circuit at a secondary side, and the cooling device which is controllable with regard to cooling power and which is integrated into the heat transfer medium circuit via the controllable fitting assigned to the heat transfer medium circuit.
 6. A water electrolysis device according to claim 5, further comprising a control and regulation device activating the fitting and/or the cooling device for the purpose of temperature regulation of the water which is fed to the ion exchanger and/or to the PEM electrolyser.
 7. A water electrolysis device according to claim 6, further comprising a speed-controllable circulation pump whose speed is controlled by the control and regulation device, wherein the speed-controllable circulation pump is arranged in the heat transfer medium circuit.
 8. A water electrolysis device according to claim 5, wherein the fitting comprises a mixing valve.
 9. A water electrolysis device according to claim 5, wherein the cooling device in the heat transfer medium circuit is connected parallel to the further heat exchanger or is connected in series to the first heat exchanger upstream of the first heat exchanger in a throughflow direction.
 10. A water electrolysis device according to claim 5, further comprising a heating device, wherein the heating device is integrated in the conduit circuit between an exit of the further heat exchanger and an entry of the PEM electrolyser, or the heating device is connected upstream of the further heat exchanger in the heat transfer medium circuit.
 11. A water electrolysis device according to claim 5, further comprising a bypass valve and a bypass conduit which can be shut-off by way of the bypass valve, wherein the bypass conduit is provided in the conduit circuit parallel to the PEM electrolyser.
 12. A water electrolysis device according to claim 5, further comprising a valve arrangement for a direction reversal of a throughflow of the PEM electrolyser, wherein the valve arrangement is assigned to the PEM electrolyser.
 13. A water electrolysis device according to claim 12, wherein an entry and an exit of the PEM electrolyser are each connected to a feeding and a discharging conduit of the conduit circuit via a 3/2-way valve of the valve arrangement.
 14. A water electrolysis device according to claim 12, wherein an entry and an exit of the PEM electrolyser are connected to a feeding and a discharging conduit of the conduit circuit via a 4/2-way valve of the valve arrangement or via a 4/3-way valve of the valve arrangement.
 15. An electrolysis device according to claim 12, wherein a reversal control re-routing water in the conduit circuit in temporal intervals by controlling valves of the valve arrangement which are assigned to the PEM electrolyser.
 16. A water electrolysis device according to claim 5, further comprising a start-up control, said start-up control leading the conduit circuit through a bypass whilst bypassing the PEM electrolyser during the start-up phase. 